tencate advancement of ooa technology technical paper
TRANSCRIPT
Advancement of Out Of Autclave (OOA) Technology at Tencate Advanced Composites, USA
Henry Villareal, Scott Unger, Frank W. Lee
Tencate Advanced Composites, USA
18410 Butterfield Blvd.
Morgan Hill, CA 95037
1. ABSTRACT
Out of autoclave (OOA), under vacuum pressure only cured processing of composites has been one of the
most important fields of interest in the composite industry in recent years. A great deal of time and
resources has been invested by many academic institutions, government agencies and the composite
industry to further the OOA technology. The advantages and disadvantages of this technology have been
chronicled in many technical publications and presentations. Tencate Advanced Composites, USA (TCAC)
has been very active in promoting and supporting the OOA technology for over 20 years. Over 5,000
airplanes used in the general aviation market were built with TCAC’s BT250E-1 epoxy system and numerous
UAV’s were manufactured using both BT250E-1 and TC250 epoxy systems with OOA processes. A specially
formulated OOA high temperature cyanate ester system (TC420) with over 500°F temperature resistance is
being used in manufacturing large heat shields in space vehicle applications. As the demand for higher
performance OOA systems continues to grow and the expectation to match or even exceed the properties
of autoclave cured systems amplifies, more technical improvements in this area have been investigated and
developed within TCAC and also through continuous collaboration with the composite industry. This paper
is a chronicle of a stage by stage advancement of TCAC’s new and exciting epoxy OOA materials and
process technologies. These new prepreg systems deliver much lower void contents after cure, are easier
to inspect under NDI Pulse Echo method and provide better overall hot-wet properties after moisture
saturation and better impact resistance.
2. INTRODUCTION
The use of composite materials in aero structures has steadily grown over the past few decades
however the recent trend, largely driven by fuel efficiency and carbon emission reductions, is
driving design engineers from more traditional metal structures to those made from composites.
Carbon and fiberglass composite structures used in commercial aerospace are growing rapidly and
the advent of the 787 and A350 aircraft has resulted in a paradigm shift in the volume of carbon
composite material usage in critical aero structures to > 50% by weight. Naturally, as the volume
of usage of composites increases to high levels, manufacturers have to look toward low cost
processes, lean techniques and automation to reduce costs and increase the pounds of structure
per hour that can be reduced. Manufacturers around the globe are investigating many variants of
Out of Autoclave (OOA) processes with a focus on cost reduction. OOA can be related to many
processes such as RTM, VARTM, In situ thermoplastic composite consolidation, thermoforming of
thermoplastic composites, et cetera; however the focus of this paper will be upon OOA processing
capabilities of TenCate Advanced Composites’ next generation thermosetting prepreg systems.
TenCate Advanced Composites (Formerly Bryte Technologies) has its roots in OOA prepreg
materials as Bryte was founded based upon a proprietary OOA centric prepregging process.
Through that process and its formulating knowledge TenCate has been supplying production ready
OOA systems into aerospace applications for over 20 years. These OOA prepreg systems are
capable of producing extremely low void (< 2%), nondestructively inspectable composite
structures using high volume, production ready oven/vacuum bag processing methods. To date
greater than 5,000 FAA certified aircraft and hundreds of production unmanned aerial vehicles
(UAV’s) and high value, high reliability space vehicles have been built utilizing TenCate’s OOA
prepreg technology. This OOA legacy is now fueling TenCate’s next generation of OOA prepreg
systems which are improved mechanical, environmental capabilities, while not hampering the low
void, NDI inspectable attributes that TenCate’s OOA materials have traditionally offered for the
company’s customers.
TenCate’s new, advanced OOA prepreg systems are focused on increasing resin system
performance for demanding aerospace environments. To accomplish this, TenCate has
engineered these next generation thermosetting resins to exhibit extremely high hot wet property
retention, the key design metric for all polymer based composites, increase toughness and
increased temperature resistance. The culmination of these efforts has resulted in the creation of
2 new epoxy products which are available as prepreg with all common fiber reinforcements in
unidirectional tape, woven and multi-axial formats.
System Description Cure Temperature
TC275 Epoxy Prepreg 275°F - 350°F
TC350-1 High Toughness Epoxy Prepreg 275°F cure with 350°F post cure
These resin systems will enable engineers to push the design envelope for OOA prepreg materials
to the same levels as those seen for traditional autoclave cured prepreg systems and set the stage
for manufacturing efficiencies that will drive recurring costs down, while minimizing scrap.
3. EXPERIMENTATION
Various experiments were conducted to evaluate Tencate’s latest OOA systems and technology.
Unidirectional tape and fabric systems of TC275 OOA prepreg system are covered in this paper in details,
and some interesting results of TC350-1 which is a high impact resistant system is discussed as well.
3.1 Thermal Analysis
Thermal analysis of resin and laminates were done with the following methods: rheology , glass transition
temperature, degree of cure and gel time.
3.1.1 Rheology
The rheology data was collected using Texas Instrument AR2000 ex. For Dynamic test a 1.0 mm gap was
used with 2.0% strain at 1 Hz. frequency. For Isothermal test a 0.6 mm gap was used with a shear rate of
1.92 1/s.
Figure 3.1 Dynamic curve of TC275
Figure 3.2 Isothermal curve of TC275
3.1.2 Glass Transition Temperature
The glass transition temperature data was tested with Perkin Elmer Dynamic Mechanical Analyzer 7e set –
up with a static force of 110 mN, dynamic force of 100 mN at a frequency of 1.0 Hz. Glass Transition
Temperature were measured on both dry and wet samples after conditioned at a humidity chamber.
Figure 3.3 Neat Resin Glass Transition Temperature of TC 275 after cured at 275F for 6 hours (DMA)
Figure 3.4 Neat Resin wet Tg of TC 275 after moisture saturation (DMA)
3.1.3 Degree of Cure
Degree of cure data was verified using Perkin Elmer Diamond DSC and TA Instrument DSCQ20. A heat rate
of 10°C/min was used. Multiple cure profiles were performed to determine the optimum cure of the
systems.
Figure 3.5 Degree of cure curve of TC275 cured at 275F for 6 hours
3.1.3 Gel Time
Gel time was determined using Omega CN76000 set at specified plate temperature.
3.2 Voids and Porosity Analysis
Void content of the laminates was done using three methods: Ultrasonic Non Destructive Inspection (NDI),
microscopy and fiber volume by acid digestion.
3.2.1 Ultrasonic NDI
Ultrasonic non- destructive (NDI) was used for the C-scanning of composite laminates. It provides images
(amplitude, thickness and B-scan) and amplitude histograms for classifying laminate quality. NDT
Automation ultrasonic immersion scanner was used and UTwin software for the data analysis. All laminates
were inspected after cure using pulse echo 5 mHz transducer.
LR#10762 TR50S/TC275 32 PLIES GAIN=11.8 VOLTAGE=400 ENERGY=820
TR50/TC275
LOT. NO.:091610-2T3
SEQ. DEBULK 275°F cure
Amp. =79.28
Figure 3.6 32 ply quasi isotropic laminate made with TR50/TC275 uni-tape shows the amplitude and a
clear view of the back wall
3k 2x2 Twill Gr/TC275 12 plies LR#10476 GAIN=13.6 Voltage= 400 Energy=820
VOLTAGE=400 ENERGY=820
13
Amp. =70.25
14
Amp. =81.35
Figure 3.7 12 ply laminate made with 2x2 twill/TC275 fabric shows the amplitude and a clear view of the
back wall
TC350 OOA GAIN= 12.8 VOLTAGE=400 ENERGY=820
LR#11341
4 ply debulk
80 plies
Amp. =84.462%
Figure 3.8 80 ply laminate made by IM7/TC350-1 tape shows the amplitude and a clear view of the back
wall
3.2.2 Microscopy
All cross section samples for microscope inspection were first potted and cured. They were then polished
using Ecomet 4000 variable speed grinder- polisher by Buehler with polishing medium polycrystalline
diamond suspension solution with 9 to 0.05 microns particles. Pictures were taken at different
magnifications using an Olympus BHT digital camera. The percent of void in each sample was evaluated
using the Image J software analyzer.
3.2.3 Fiber Volume by acid digestion.
Acid digestion was performed with the use of Mars Machine by CEM Corporation. Samples were placed
inside a plastic vessel with 40 ml. of concentric nitric acid and run through a pre-determined cycle.
3.3 Debulking and Sample Fabrication
The debulking procedure for OOA laminates was one of the important factors to achieve high laminate
quality. The prepregs were debulked every 2 plies to 4 plies to minimize the trapped air within the system
before curing. The layup and cure of each product were done per recommended cure cycles unless
otherwise specified. All data was generated using vacuum bag process only and laid up using LU-1.5
reduced caul plate method (Fig. 3.1) for TC275 and LU-1 method (Fig. 3.2) for TC350-1. Autoclave cured
laminates, which were used for comparison, were made with the same debulking procedures.
3.4 Resin Preparation, Mixing and Coating
Proper degassing procedure was used during the preparation of neat resins to minimize the entrapped air
in the resins. Vacuum level was maintained at least 28 in. of Hg or higher during resin mixing to obtain
optimum degassing of the resins at the mixing temperature range.
3.5 Prepregging /Laminating
Prepregging was performed using a refined and specialized film and calendaring methodology which
produces prepregs optimized for use in out of autoclave processes.
3.5.1 Prepreg Physical Testing
The appearance and the quality of the prepregs were validated by via the resin flow, resin content and
volatile tests,
3.5.2 Laminate Fabrication
All laminates fabricated for each mechanical test was based on the ASTM test method as listed.
3.5.3 Debulk, Lay-up and Cure
An excellent debulking procedure was necessary to minimize entrapped air between plies. Pulled vacuum
was at least at 27 in. Hg. TC275 system was debulked every 4 plies for 5-10 min. each (Figure 3.9) until the
needed plies for the sample was achieved while TC350-1 was debulked every 4 plies for 15 min. until all the
needed plies were laid up for the samples . For TC 275 and TC350-1 woven fabric systems, both systems
were debulked every 2 plies for 5 – 10 min.
Vacuum Nylon Bag
Non woven bleeder TX1040
Non porous FEP
Bottom Tool
Prepreg
Breather Pad
Figure 3.9
An additional ply of porous Teflon coated glass(TX1040) and 1 ply of non woven bleeder were used to help
the removal of entrapped air and it was replaced after being used for 2 -3 times of debulking
Vacuum
Non Porous FEP
Non porous FEP
Figure 4.2
After the debulking step, TC275 system was processed using the following bagging technique (Figure 3.11)
to make all the samples for mechanical testing.
Breather Pad
Prepreg
Nylon Bag
Caul Plate
Bottom Tool
Figure 3.10
Thermocouple wires were used to monitor and record the temperature and a vacuum sensor was used to
monitor the vacuum during the curing process.
Figure 3.11 (LU-1.5 method)
TC350-1 was laid up with the regular LU-1 bleed schedule which was similar to LU-1.5 bleed RCP with the
exclusion of TX1040 and the top caul plate used was the same size of the actual uncured laminate. The
vacuum bag integrity was checked prior to to starting cure cycle and leak rate shall not exceed 5 in. Hg in 5
minutes.
TC 275 cure cycle used to make all the mechanical test samples was listed as the following:
a. Pull vacuum (minimum 28 in. Hg)
b. Heat at 1°F/min to 180± 5°F
c. Hold at 180°F± 5°F for 1 hour
d. Heat at 2°F/min to 275± 5°F
e. Hold at 275°F± 5°F for 6 hours
Vacuum
Nylon Bag
Reduced top caul plate 0.25 in thick
Non-porous FEP
Breather string TX1040 Porous Teflon coated glass
Silicone dam
Bottom Tool
Part
Non-porous FEP
Breather pad
Non woven Breather
Strings
Dam
Note: The breather string must be in the edge of the part, must not lay on the top of the panel and must extend out past the seal to touch the breather
pad material as shown below
f. Cool at 5 to 7°F/min to <140°F
g. Removed parts from oven below 120°F
Figure 3.12 TC275 Cure Cycle
3.5.4 Machining, Drying and Conditioning
All cured laminates were C-scanned by Ultrasonic NDI scanner to assess the quality. All scanning results
were evaluated and at times analyzed by cross section method.
All mechanical test specimens were machined according to specifications based on the ASTM methods.
Before mechanical testing, all specimens were dried at 212°F for 1 hour. After drying, specimens were kept
at room temperature environment of 70±10 °F or in a desiccator until the tests.
For environmental conditioning, all specimens were put inside a humidity chamber at 145°F and 85%
humidity after being dried at 212° F for one hour, unless specified. The moisture saturation was achieved
when the traveler samples were observed to have change less than 0.05% for two consecutive 7 day
periods.
75
125
175
225
275
325
375
0 105 165 575 600
Time (min)
0
20
40
60
80
100
120
Te
mp
era
ture
Temp Vacuum
215
in H
g
3.5.5 Mechanical Testing Methods
ASTM test methods were used for all the testing of laminate samples. An average of 5 specimens for each
test was done. Specimens were tested at different environment conditions and defined as:
RTD = 70±5°F, room temperature dry
ETD = 180±5°F dry
ETW = 180±5°F, wet (saturated)
CTD = -65±5°F, dry
Type and ASTM Method Used
Tests ASTM Method
Tensile Strength & Modulus ASTM 3039
Compression Strength& Modulus ASTM D 695
Compression Combined Loading Test ASTM D 6641
Short Beam Shear ASTM D2344
Flexural Strength & Modulus ASTM D 790
In Plane- Shear Strength & Modulus ASTM D 3518
Open Hole Tensile Strength ASTM D 5766
Open Hole Compression Strength ASTM D 6484
Compression After Impact test ASTM D 7136/7137
4. Discussion and Results
A major source of voids in composite laminates, especially processed with out of autoclave method (OOA),
is entrapped air (1). Voids in the resultant laminates will lead to reductions in strength, high variability in
design allowable data and will create major issues with non-destructive inspection techniques should the
void levels go beyond 2%. It is critical to design prepreg systems and lay-up methods to remove all the
entrapped air effectively and efficiently. A prepreg system , which provides pathway for more rapid
removal of air, is desired (2). An excellent debulking procedure during lay-up is essential to minimize
trapped air between plies. During the cure process, air must be removed from all locations in the part
through breathable edge dams prior to the gelation of the resin (3). Those above mentioned criteria are as
important as the formulation of a good OOA prepreg system which includes resin and fiber.
4.1 TC 275
TC275 prepreg system was developed to meet all the criteria in OOA process and also to meet the
demanding environmental conditioned requirements which are to exhibit very high hot wet property
retention. The first study of the system was to develop a good cure profile. The system was cured at 4, 5
and 6 hours at 275°F and as the data presented in Table 4.1. These data were very comparable to each
other. From Table 4.2, the 4 hr. cured laminate samples were observed to pick up slightly higher moisture
content compared to both 5 and 6 hour cures at 275°F. This might indicate that the 4 hour cure sample at
this cure temperature and time did not offer the most optimal cure level. After careful evaluation of these
data we observed that this system can be cured at this time span, but the 6 hour cure seemed to be offer
slightly better hot/wet mechanical numbers. The system was also cured in a temperature range at 275°F (6
hours), 300°F (3 hours) and 350°F (2 hours). The resultant laminates were tested. The mechanical
properties and glass transition temperatures (Tg ) were listed in Table 4.3 and Table 4.4 for tape and fabric
respectively. The higher cure temperatures gave slightly higher glass transition temperatures. The
mechanical properties, however, were very close to each other. The higher cure temperature laminates
absorbed a higher amount of moisture upon saturation. This was due to the higher free volume expansion
of the matrix at higher temperature cures. It was observed, based on the very similar dry, hot and hot/wet
mechanical properties, that this system could be processed at 275°F to 350°F with the specific cure times.
It is a matter of choice for the users based on their own preferences, capabilities and tool requirements.
TC275 was found to have very low moisture absorption after saturation. The moisture saturation
percentage was under 0.4% for laminates and <1.2% for neat resin cured after 6 hours at 275°F. We
conditioned all laminate samples at 145°F and 85% humidity and the neat resin was conditioned at 160°F
and 85% humidity. The key to have a very good hot/wet resistant resin system or prepreg system is to have
low moisture uptake after moisture exposure. The typical epoxy resin system picks up about 3-4% by
weight of moisture at saturation. The Tg value retention of this system after moisture saturation was about
90%.
The mechanical properties of laminates made from TR50S/TC275 tape and 2x2 twill Gr/TC275 woven
prepregs were cured at 275°F for 6 hours (Table 4.5 and Table 4.6) The data showed again very high
hot/wet retention values, between mid-80 to upper 90% retention. Large thick and thin parts were made
via OOA process with TC275. These parts are shown in Figure 4.1. The NDI C-scan of those panels showed
very clear back wall transmission and high amplitude. The polished cross sections of these panels as shown
in Figure 4.2 were usually below 0.5%. It is a moderately impact resistant system, based on the CAI number.
Mechanical Tests 4 hr. Cure 5 hr. Cure 6 hr. Cure
RT HWT RT HWT RT HWT
Compression Strength(ksi) 200.0 194.0 191.1 204.1 207.7 194.2
Compression Modulus(msi) 17.5 15.3 18 17.5 18.5 16.6
Short Beam Strength(ksi) 12.4 8.6 12.9 9.2 12.9 8.6
Flexural Strength(ksi) 240.3 169.5 244.8 187.9 240.6 197.5
Flexural Modulus(msi) 12 11 12 11 13 13
Tensile Strength(ksi) 306.2 283.0 325.3 274.7 310.9 303.7
Tensile Modulus(msi) 18.8 11.5 19.6 10.7 17.6 18.9
TG by DMA – (°C) 147.5
(dry)
130.9
(wet)
146.1
(dry)
132.0
(wet)
144.9
(dry)
128.9
(wet)
Table 4.1 Material Property Summary 275°F Cure (All Raw Data)
Cure Profile % Moisture
4 hr. Cure @ 275°F 0.4218
5 hr. Cure @ 275°F 0.3865
6 hr. Cure @ 275°F 0.3850
3 hr. Cure @ 300°F 0.4693
2 hr. Cure @ 350°F 0.4929
Table 4.2 Moisture Absorption Summary of TR50S/TC275 Unidirectional Tape
*Humidity Chamber Setting @ 85%RH and 145 F
Mechanical Tests 275° Cure (LR# 10210) 300° Cure (LR# 10229) 350° (LR# 10246)
0° 90° 0° 90° 0° 90°
TS
(ksi)
Room Temp. 344.1 8.0 318.6 9.4 329.8 8.6
180°F(dry) 382.9 6.62 340.1 6.1 337.9 6.8
14 Days HW 344.4 6.9 344.5 6.5 350.7 6.2
21 Days 345.3 332.8 342.6
30 Days 323.7 317.4 335.2
Saturated 336.1 303.5 331.9
-65°F 340.7 314.2 348.3
TM
(Msi)
Room Temp. 19.4 1.1 17.6 1.1 19.5 1.1
180°F(dry) 21.3 1.0 20.8 1.0 21.0 0.9
14 Days HW 21.0 1.0 20.4 0.8 21.4 0.9
21 Days 20.6 21.0 20.5
30 Days 20.8 21.2 21.0
Saturated 20.9 21.8 20.6
-65°F 18.8 17.3 19.3
CS
(ksi)
Room Temp. 216.5 210.0 187.0
180°F(dry) 205.1 207.1 195..5
14 Days HW 202.7 249.2 187.2
21 Days 214.6 212.6 213.9
30 Days 213.3 233.8 205.2
Saturated 196.7 192.3 192.4
-65°F 219.8 244.8 213.3
CM
(Msi)
Room Temp. 19.2 1.4 20 1.6 18.4 1.4
180°F(dry) 19.5 1.2 21.2 1.2 17.6 1.1
14 Days HW 17.9 1.0 17.7 1.0 17.0 0.9
21 Days 17.3 0.9 18.2 1.0 16.6 0.9
30 Days 17.7 1.2 17.1 1.2 17.5 1.4
Saturated 18.3 16.7 14.8
-65°F 18.8 1.6 19.3 1.4 18.5 1.3
FS
(ksi)
Room Temp. 243.7 276.3 235.8
180°F(dry) 201.9 218.6 195.2
14 Days HW 197.1 191.3 190.2
21 Days 207.9 196.4 188.1
30 Days 177.0 172.7 170.0
Saturated 205.8 192.2 195.6
-65°F 279.1 299.9 301.6
FM
(Msi)
Room Temp. 12.5 14.2 12.5
180°F(dry) 12.3 13.4 11.7
14 Days HW 12.9 12.5 12.0
21 Days 12.3 11.9 11.5
30 Days 11.6 11.6 11.7
Saturated 12.8 11.8 12.0
-65°F 12.2 12.7 12.9
SBS*
(ksi)
Room Temp. 12.9 12.5 13.3
180°F(dry) 9.5 9.5 9.9
14 Days HW 8.3 8.8 8.8
21 Days 8.3 8.3 8.6
30 Days 8.2 8.10 8.5
Saturated 8.5 8.4 8.5
-65°F 17.2 16.6 16.0
CS
6641
(ksi)
90/0/90
Room Temp. 232.6 224.3 236.0
180°F(dry) 225.7 220.3 216.2
14 Days HW 198.5 209.0 213.7
21 Days 218.3 212.4 199.1
30 Days 187.9 208.9 201.9
Saturated 205.8 204.5 202.8
-65°F 271.6 269.6 278
Tg by DMA Room Temp. 144.8°C 148.1°C 169.6°C
14 Days 132.2°C 133.3°C 150.1°C
21 Days 130.6°C 134.8°C 149.9°C
30 Days 129.3°C 137.3°C 146.2°C
Saturated 128.9°C 136.9°C 149.8°C
Table 4.3 Testing results of TR50S, 15K/TC275 Unidirectional Tape Normalized to 60% FV
*SBS data not normalized
Mechanical Tests 275° Cure (LR# 10210) 300° Cure (LR# 10229) 350° (LR# 10246)
0° 90° 0° 90° 0° 90°
TS
(ksi)
Room Temp. 146.1 137.0 141.4 140.9 146.0 133.9
180°F(dry) 151.7 142.3 143.2 143.7 142.8 137.9
21 Days HW 152.9 144.8 139.0 139.8 140.8 143.3
Saturated 145.5 149.7 145.0 141.5 134.4 141.8
-65°F 147.0 143.1 135.6 139.3 127.9 126.6
TM
(Msi)
Room Temp. 10.0 10.8 10.3 10.1 10.5 11.0
180°F(dry) 10.8 10.0 10.8 11.0 10.7 10.7
21 Days HW 10.8 10.6 10.7 10.9 11.1 11.0
Saturated 10.8 11.1 10.8 11.0 10.8 11.1
-65°F 9.2 9.4 9.6 8.8 9.5 9.3
CS
(ksi)
Room Temp. 114.1 118.6 114.5 117.9 114.2 119.3
180°F(dry) 105.8 108.0 107.0 108.4 104.6 113.1
21 Days HW 101.9 100.4 101.6 104.2 106.1 104.2
Saturated 98.5 98.8 103.4 99.3 103.4 97.1
-65°F 122.5 126.5 125.0 125.7 126.3 127.1
CM
(Msi)
Room Temp. 9.6 9.5 9.3 9.4 9.5 9.6
180°F(dry) 8.9 8.9 9.0 9.2 8.9 9.1
21 Days HW 8.8 9.0 9.0 8.9 8.6 8.9
Saturated 8.6 9.2 8.1 8.8 8.8 9.1
-65°F 9.8 9.5 9.2 9.1 9.66 9.8
FS
(ksi)
Room Temp. 150.8 148.9 154.4
180°F(dry) 125.5 123.9 130.1
21 Days HW 115.6 118.1 114.8
Saturated 115.0 116.7 117.5
-65°F 169.8 176.1 176.4
FM
(Msi)
Room Temp. 7.7 7.8 7.9
180°F(dry) 7.4 7.4 7.4
21 Days HW 7.4 7.4 7.5
Saturated 7.2 7.3 7.3
-65°F 7.7 7.9 7.9
SBS*
(ksi)
Room Temp. 10.5 10.0 10.5
180°F(dry) 8.1 7.7 8.3
21 Days HW 7.1 7.4 6.9
Saturated 7.4 7.2 7.2
-65°F 12.7 12.4 12.4
CS
6641
(ksi)
90/0/90
Room Temp. 100.0 99.4 102.3 96.6 107.8 107.1
180°F(dry) 87.6 84.4 89.3 89.6 86.4 86.8
21 Days HW 79.4 84.3 85.0 81.6 82.4 84.0
Saturated 71.9 87.1 78.3 83.9 80.0 84.0
-65°F 134.9 126.2 140.3 134.7 126.5 130.8
Tg by DMA Room Temp. 145.3°C 152.8°C 164.0°C
21 Days 131.8°C 1391°C 150.7°C
Saturated 134.7°C 136.4°C 149.1°C
Table 4.4 Testing result of G30-500 3k, 2x2 Twill GR/TC275 Fabric Normalized to 60% FV
*SBS data not normalized
Thick Part
Thin Parts
Figure 4.1 Parts made by TC275 OOA System
TR50S/TC275
0°
LR# 10041
Void = 0.063%
TR50S/TC275
90°
LR# 9881
Void = 0.198%
G30-500 3k, 2x2
Twill GR/TC275
90°
LR# 9867
Void = 0.345%
G30-500 3k, 2x2
Twill GR/TC275
90°
LR# 9867
Void = 0.057%
Figure 4.2 Microscopic Cross-Section of TC275 OOA System
*10x 5 magnifications
Mechanical Tests RTD ETD ETW CTD
0° Tensile Strength (ksi) 344.1 382.9 336.1 340.7
0° Tensile Modulus (msi) 19.5 21.3 20.9 18.8
90° Tensile Strength (ksi) 7.99 6.6 6.9* NA
90° Tensile Modulus (msi) 1.1 0.96 1.0* NA
0° Compression Strength (ksi) 216.5 205.1 196.7 219.8
0° Compression Modulus (msi) 19.2 19.5 18.3 18.8
0° Flex Strength (ksi) 243.7 201.9 205.8 279.1
0° Flex Modulus (msi) 12.5 12.2 12.8 12.2
CS 6641(ksi) 232.6 225.7 205.8 271.6
Short Beam Shear (ksi) 12.9 9.5 8.5 17.2
Open Hole Tensile (ksi) 67.6 70.7
Open Hole Compression(msi) 39.6 35.1
In Plane Shear Strength (ksi) 11.9 11.0
In Plane Shear Modulus(msi) 0.447 0.475
CAI Strength (ksi) 1150 in-lb 35.7
CAI Strength (ksi) 1500 in-lb 21.1
Table 4.5 Testing result of TR50S/TC275 Unidirectional Tape
*14 days in the humidity chamber (not saturated)
Mechanical Tests RTD ETD ETW CTD
0° Tensile Strength (ksi) 146.1 151.7 145.5 147.0
0° Tensile Modulus (msi) 10.1 10.8 10.8 9.2
90° Tensile Strength (ksi) 137.0 142.3 149.7 143.1
90° Tensile Modulus (msi) 10.8 10.8 11.0 9.4
0° Compression Strength (ksi) 114.1 105.8 98.5 122.5
0° Compression Modulus (msi) 9.6 8.9 8.6 9.8
90° Compression Strength (ksi) 118.6 108.0 98.8 126.5
90° Compression Modulus (msi) 9.5 8.9 9.2 9.5
0° Flex Strength (ksi) 150.8 125.5 115.0 170.0
0° Flex Modulus (msi) 7.7 7.4 7.2 7.7
Short Beam Shear (ksi) 10.5 8.1 7.4 12.7
CAI Strength (ksi) 1500 in-lb 34.2
Table 4.6 Testing results of G30-500 2x2 Twill Gr/ TC275 Fabric
4.2 TC 350-1
The TC350-1 technology evolved from one of our standard toughened 350°F cured epoxy prepreg systems,
TC 350. It was intended to develop a higher toughness epoxy system which could be cured with an out of
autoclave (OOA) process. Due to some tooling constraints for some potential customers we have also
developed and established a lower temperature cure profile which can be cured initially at 275F and then
free standing post cured at 350°F for 2 hours. The data for this study was presented in Table 4.7. Based on
the data established up to this point, it is recommended that TC 350-1 could initially be cured at 275°F for 3
hours via OOA process and then free standing post cured at 350°F for 2 hours.
As it has been well documented, the debulking step is very important to make good panels. Great efforts
were done to investigate this step and maximize the outcome of the laminates. Table 4.8 shows that
different attempts were used to investigate this important step. We have tried 2 ply, 4 ply and RT and
warm debulking within 10-15 minutes and the resultant laminates were observed to be all very good and
similar. It was observed that this system is very user friendly, in handling and shop life.
We compared the OOA cured data vs. autoclave cured data in Table 4.9. The values were similar if not
identical. This database showed that this system was capable to be processed via OOA to obtain autoclave
cured laminate properties. The polished cross sections of both IM7/TC350-1 tape and AS4 PW/TC 350-1 as
observed in Figure 4.3 showed both systems had very minimum voids (<0.4%). Part of the reasons for this
excellent data generated in the OOA process and was comparable to the autoclave process of the same
system was due to the very low void content after OOA cure. As it is quite clear to very faithful participant
of the OOA technology, the debulking step is very important to make good panels. Great efforts were done
to investigate this step and maximize the quality of the laminates. Table 4.8 shows that different attempts
were used to investigate this important step. We have utilized 2 ply, 4 ply and RT and warm debulking
within 10-15 minutes and the resultant laminates were observed to be all very good and similar. It was
observed that this system is very robust.
The compression after impact (CAI) value when cured under autoclave environment yield very good values
(37 ksi, 1500 in-lb) and the CAI value of TC350-1 processed by OOA is being tested by an accredited third
party test lab. The value will be available at the SAMPE presentation. All the environmental (160F and 85%
humidity) conditioned data are being generated. Thick laminates of up to 80 plies were made with very
clear C-scan back wall due to very minimum voids (Figure 3.8). Large and complex parts are being made
both internally and externally.
Cure Temperature SBS(ksi) TG(°C) Degree of Cure (%)
275°F for 3 hrs 17.8 147.6 66.8
275°F for 5 hrs 18.3 156.8 71.6
275°F for 3 hrs then PC to 350°F for 1 hr 19.9 197.2 82.4
275°F for 5 hrs then PC to 350°F for 1 hr 20.1 195.5 85.7
275°F for 3 hrs then PC to 350°F for 2 hrs 20.7 201.6 84.8
275°F for 5 hrs then PC to 350°F for 2 hrs 20.1 209.9 84.6
350°F cure for 2 hours 20.1 208.0 84.7
Table 4.7 OOA Cure Profile Study of TC350-1
Autoclave
0°
Void = 0.468%
Autoclave
90°
Void = 0.296%
Oven (OOA)
0°
Void = 0.339%
Oven (OOA)
90°
Void = 0.120%
Figure 4.3 Microscopic Cross-Section of AS4C 3k PW, 202gsm/TC350-1 (10x5 magnification)
Debulk Procedure SBS(ksi) TG(°C) CS(ksi) CM(Msi)
4 ply debulk with FEP
(Autoclave Cure)
20.9 208.3 263.28
23.588
4 ply debulk with FEP
(Oven Cure)
20.1 209.8 271.68
24.056
4 ply warm debulk with FEP
(Oven Cure)
20.0
2 ply debulk with FEP
(Oven Cure)
19.0 266.38 23.272
4 ply debulk with TX1040
(Oven Cure)
20.3
2 ply debulk with TX1040
(Oven Cure)
21.1
Table 4.8 Debulk Study of TC350-1
Type of Test OOA cured Laminate
(RTD)
Autoclave cured Laminate
(RTD)
0° Tensile Strength (ksi) 395.1 381.8
0° Tensile Modulus (msi) 23.6 23.0
0° Compression Strength (ksi) 271.6 263.3
0° Compression Modulus (msi) 23.3 23.5
0° Flex Strength (ksi) 335.5 NA
0° Flex Modulus (msi) 13.9 NA
Short Beam Shear (ksi) 20.1 20.9
CAI Strength (ksi) 1500 in-lb TBD 37.4
Table 4.9 Testing results of IM7/TC350-1 Unidirectional Tape
5. Conclusion
Out of autoclave (OOA) materials development over the past 10 years has been very Edisonian in nature
and not typically embodied the manufacturing processes with respect to both the materials and the
processes used to produce parts by OOA methodologies. Prepreg system development has therefore not
typically encompassed the materials and processes required to produce large scale production parts that
not only meet design requirements but are also very robust from a manufacturing and non destructive
inspection perspective. TenCate is addressing this next generation need with its TC275 and TC350-1 OOA
prepreg systems. TC275 offers mechanical property performance similar to autoclave cured structural
composite materials but also brings to the design space a product that is very friendly to the OOA
manufacturing processes currently employed in the industry, has standard setting hot/wet performance
and can be easily inspected with current non-destructive inspection techniques. TC350-1 embodies
similar manufacturing and inspection attributes to TC275, but also brings increased toughness and open
hole strength properties that have classically only been available in autoclave curable composite materials.
Another OOA development that Tencate has been focusing on is a high temperature resistant (Tg>300°C)
cyanate based system with excellent structural integrity, toughness and manufacturability for space, launch
vehicle and other critical aerospace applications.
6. References
1. Campbell, F. Manufacturing Process For Advanced Composites, New York, New York; Elsevier, 2004
2. Taveres, S. S., Muchaud, V., Manson, J-A.E., Through thickness air permeability of prepregs during
cure. Composites: Part A, 2009. 40: P. 1587.
3. Jackson, K., Crabtree, M., Autoclave quality composites tooling for composite from vacuum bag only
processing. 47th
International SAMPE Symposium, 2002.